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Kenneth H. Rosen Chapter 8 Trees

Discrete Mathematics and Its Applications. Kenneth H. Rosen Chapter 8 Trees Slides by Sylvia Sorkin, Community College of Baltimore County - Essex Campus. Tree. Definition 1. A tree is a connected undirected graph with no simple circuits.

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Kenneth H. Rosen Chapter 8 Trees

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  1. Discrete Mathematics and Its Applications Kenneth H. Rosen Chapter 8 Trees Slides by Sylvia Sorkin, Community College of Baltimore County - Essex Campus

  2. Tree Definition 1. A tree is a connected undirected graph with no simple circuits. Theorem 1. An undirected graph is a tree if and only if there is a unique simple path between any two of its vertices.

  3. Which graphs are trees? b) a) c)

  4. Specify a vertex as root Then, direct each edge away from the root. ROOT c)

  5. Specify a root. Then, direct each edge away from the root. ROOT a)

  6. Specify a root. Then, direct each edge away from the root. ROOT a)

  7. Specify a root. Then, direct each edge away from the root. ROOT a) A directed graph called a rooted tree results.

  8. What if a different root is chosen? Then, direct each edge away from the root. ROOT a)

  9. What if a different root is chosen? Then, direct each edge away from the root. ROOT a)

  10. What if a different root is chosen? Then, direct each edge away from the root. ROOT a)

  11. What if a different root is chosen? Then, direct each edge away from the root. ROOT a) A different rooted tree results.

  12. Jake’s Pizza Shop Tree Owner Jake Manager Brad Chef Carol Waitress Waiter Cook Helper Joyce Chris Max Len

  13. A Tree Has a Root TREE ROOT Owner Jake Manager Brad Chef Carol Waitress Waiter Cook Helper Joyce Chris Max Len

  14. Leaf nodes have no children Owner Jake Manager Brad Chef Carol Waitress Waiter Cook Helper Joyce Chris Max Len LEAF NODES

  15. A Tree Has Levels Owner Jake Manager Brad Chef Carol Waitress Waiter Cook Helper Joyce Chris Max Len LEVEL 0

  16. Level One Owner Jake Manager Brad Chef Carol Waitress Waiter Cook Helper Joyce Chris Max Len LEVEL 1

  17. Level Two Owner Jake Manager Brad Chef Carol Waitress Waiter Cook Helper Joyce Chris Max Len LEVEL 2

  18. Sibling nodes have same parent Owner Jake Manager Brad Chef Carol Waitress Waiter Cook Helper Joyce Chris Max Len SIBLINGS

  19. Sibling nodes have same parent Owner Jake Manager Brad Chef Carol Waitress Waiter Cook Helper Joyce Chris Max Len SIBLINGS

  20. A Subtree ROOT Owner Jake Manager Brad Chef Carol Waitress Waiter Cook Helper Joyce Chris Max Len LEFT SUBTREE OF ROOT

  21. Another Subtree ROOT Owner Jake Manager Brad Chef Carol Waitress Waiter Cook Helper Joyce Chris Max Len RIGHT SUBTREE OF ROOT

  22. Internal Vertex A vertex that has children is calledan internal vertex. The subtree at vertex v is the subgraph of the tree consisting of vertex v and its descendants and all edges incident to those descendants.

  23. How many internal vertices? Owner Jake Manager Brad Chef Carol Waitress Waiter Cook Helper Joyce Chris Max Len

  24. Binary Tree Definition 2’. A rooted tree is called a binary tree if every internal vertex has no more than 2 children. The tree is called a full binary tree if every internal vertex has exactly 2 children.

  25. Ordered Binary Tree Definition 2’’. An ordered rooted tree is a rooted tree where the children of each internal vertex are ordered. In an ordered binary tree, the two possible children of a vertex are called the left child and the right child, if they exist.

  26. Tree Properties Theorem 2. A tree with N vertices has N-1 edges. Theorem 5. There are at most 2H leaves in a binary tree of height H. Corallary. If a binary tree with L leaves is full and balanced, then its height is H = log2 L .

  27. An Ordered Binary Tree Lou Hal Max Ken Sue Ed Joe Ted

  28. Parent • The parent of a non-root vertex is the unique vertex u with a directed edge from u to v.

  29. What is the parent of Ed? Lou Hal Max Ken Sue Ed Joe Ted

  30. Leaf • A vertex is called a leaf if it has no children.

  31. How many leaves? Lou Hal Max Ken Sue Ed Joe Ted

  32. Ancestors • The ancestors of a non-root vertex are all the vertices in the path from root to this vertex.

  33. How many ancestors of Ken? Lou Hal Max Ken Sue Ed Joe Ted

  34. Descendants • The descendants of vertex v are all the vertices that have v as an ancestor.

  35. How many descendants of Hal? Lou Hal Max Ken Sue Ed Joe Ted

  36. Level • The level of vertex v in a rooted tree is the length of the unique path from the root to v.

  37. What is the level of Ted? Lou Hal Max Ken Sue Ed Joe Ted

  38. Height • The height of a rooted tree is the maximum of the levels of its vertices.

  39. What is the height? Lou Hal Max Ken Sue Ed Joe Ted

  40. Balanced • A rooted binary tree of height H is called balanced if all its leaves are at levels H or H-1.

  41. Is this binary tree balanced? Lou Hal Max Ken Sue Ed Joe Ted

  42. Searching takes time . . . So the goal in computer programs is to find any stored item efficiently when all stored items are ordered. A Binary Search Tree can be used to store items in its vertices. It enables efficient searches.

  43. A Binary Search Tree (BST) is . . . A special kind of binary tree in which: 1. Each vertex contains a distinct key value, 2. The key values in the tree can be compared using “greater than” and “less than”, and 3. The key value of each vertex in the tree is less than every key value in its right subtree, and greater than every key value in its left subtree.

  44. ‘J’ Shape of a binary search tree . . . Depends on its key values and their order of insertion. Insert the elements ‘J’ ‘E’ ‘F’ ‘T’ ‘A’ in that order. The first value to be inserted is put into the root.

  45. ‘J’ ‘E’ Inserting ‘E’ into the BST Thereafter, each value to be inserted begins by comparing itself to the value in the root, moving left it is less, or moving right if it is greater. This continues at each level until it can be inserted as a new leaf.

  46. ‘J’ ‘E’ Inserting ‘F’ into the BST Begin by comparing ‘F’ to the value in the root, moving left it is less, or moving right if it is greater. This continues until it can be inserted as a leaf. ‘F’

  47. ‘J’ ‘T’ ‘E’ Inserting ‘T’ into the BST Begin by comparing ‘T’ to the value in the root, moving left it is less, or moving right if it is greater. This continues until it can be inserted as a leaf. ‘F’

  48. ‘J’ ‘T’ ‘E’ ‘A’ ‘F’ Inserting ‘A’ into the BST Begin by comparing ‘A’ to the value in the root, moving left it is less, or moving right if it is greater. This continues until it can be inserted as a leaf.

  49. ‘A’ What binary search tree . . . is obtained by inserting the elements ‘A’ ‘E’ ‘F’ ‘J’ ‘T’ in that order?

  50. ‘A’ ‘E’ ‘F’ ‘J’ ‘T’ Binary search tree . . . obtained by inserting the elements ‘A’ ‘E’ ‘F’ ‘J’ ‘T’ in that order.

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